Copying and counting are useful primitive operations for computation and construction. We have made DNA crystals that copy and crystals that count as they grow. For counting, 16 oligonucleotides assemble into four DNA Wang tiles that subsequently crystallize on a polymeric nucleating scaffold strand, arranging themselves in a binary counting pattern that could serve as a template for a molecular electronic demultiplexing circuit. Although the yield of counting crystals is low, and per-tile error rates in such crystals is roughly 10%, this work demonstrates the potential of algorithmic self-assembly to create complex nanoscale patterns of technological interest. A subset of the tiles for counting form information-bearing DNA tubes that copy ...
Abstract. DNA self-assembly is emerging as a key paradigm for nano-technology, nano-computation, and...
For robust molecular implementation of tile-based algorithmic self-assembly, methods for reducing e...
Biology makes things far smaller and more complex than anything produced by human engineering. The b...
Bottom-up fabrication of nanoscale structures relies on chemical processes to direct self-assembly. ...
While biology demonstrates that molecules can reliably transfer information and compute, design prin...
Algorithmic self-assembly, a generalization of crystal growth processes, has been proposed as a mech...
Algorithmic self-assembly, a generalization of crystal growth, has been proposed as a mechanism for ...
Molecular biology provides an inspiring proof-of-principle that chemical systems can store and proc...
A major challenge in practical DNA tile self-assembly is the minimization of errors. Using the kinet...
Algorithms and information, fundamental to technological and biological organization, are also an es...
Approaches to DNA-based computing by self-assembly require the use of D. T A nanostructures, called...
Algorithmic self-assembly has been proposed as a mechanism for autonomous DNA computation and for bo...
Chemical self-replicators are of considerable interest in the field of nanomanufacturing and as a mo...
Self-assembly creates natural mineral, chemical, and biological structures of great complexity. Ofte...
Biology provides the synthetic chemist with a tantalizing and frustrating challenge: to create comp...
Abstract. DNA self-assembly is emerging as a key paradigm for nano-technology, nano-computation, and...
For robust molecular implementation of tile-based algorithmic self-assembly, methods for reducing e...
Biology makes things far smaller and more complex than anything produced by human engineering. The b...
Bottom-up fabrication of nanoscale structures relies on chemical processes to direct self-assembly. ...
While biology demonstrates that molecules can reliably transfer information and compute, design prin...
Algorithmic self-assembly, a generalization of crystal growth processes, has been proposed as a mech...
Algorithmic self-assembly, a generalization of crystal growth, has been proposed as a mechanism for ...
Molecular biology provides an inspiring proof-of-principle that chemical systems can store and proc...
A major challenge in practical DNA tile self-assembly is the minimization of errors. Using the kinet...
Algorithms and information, fundamental to technological and biological organization, are also an es...
Approaches to DNA-based computing by self-assembly require the use of D. T A nanostructures, called...
Algorithmic self-assembly has been proposed as a mechanism for autonomous DNA computation and for bo...
Chemical self-replicators are of considerable interest in the field of nanomanufacturing and as a mo...
Self-assembly creates natural mineral, chemical, and biological structures of great complexity. Ofte...
Biology provides the synthetic chemist with a tantalizing and frustrating challenge: to create comp...
Abstract. DNA self-assembly is emerging as a key paradigm for nano-technology, nano-computation, and...
For robust molecular implementation of tile-based algorithmic self-assembly, methods for reducing e...
Biology makes things far smaller and more complex than anything produced by human engineering. The b...